65 Publications (Page 1 of 3)
2024
Genetic ablation ofImmtinduces a lethal disruption of the MICOS complex. Life Science Alliance
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2023
CRISPR-Cas9-mediated insertion of a short artificial intron for the generation of conditional alleles in mice. STAR Protocols
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Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Novel methods for the generation of genetically engineered animal models. Bone
. | Journal Article
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
Supplementary Data from Neuroblastoma Formation Requires Unconventional CD4 T Cells and Arginase-1–Dependent Myeloid Cells
2022
Caspase-8 and FADD prevent spontaneous ZBP1 expression and necroptosis.Rodriguez, Diego A⋅Quarato, Giovanni⋅Liedmann, Swantje⋅Tummers, Bart⋅Zhang, Ting⋅Guy, Cliff⋅Crawford, Jeremy Chase⋅Palacios, Gustavo⋅Pelletier, Stephane⋅Kalkavan, Halime⋅Shaw, Jeremy J P⋅Fitzgerald, Patrick⋅Chen, Mark J⋅Balachandran, Siddharth and Green, Douglas RProceedings of the National Academy of Sciences of the United States of America, vol. 119, (no. 41), pp. e2207240119, October 11, 2022.
| Journal Article
Caspase-8 and FADD prevent spontaneous ZBP1 expression and necroptosis. Proceedings of the National Academy of Sciences
Novel methods for the generation of genetically engineered animal models.Cassidy, Annelise⋅Onal, Melda and Pelletier, StephaneBone, pp. 116612, November 12, 2022.
| Journal Article
One-step generation of a conditional allele in mice using a short artificial intron
One-step generation of a conditional allele in mice using a short artificial intron. Heliyon
. | Journal Article
2021
Neuroblastoma formation requires unconventional CD4 T cells and Arginase-1-dependent myeloid cells.
Cancer Research. | Journal Article
SCYL1 disease and liver transplantation diagnosed by reanalysis of exome sequencing and deletion/duplication analysis of SCYL1.McNiven, Vanda⋅McNiven, Vanda⋅Gattini, Daniela⋅Gattini, Daniela⋅Siddiqui, Iram⋅Siddiqui, Iram⋅Pelletier, Stephane⋅Pelletier, Stephane⋅Brill, Herbert⋅Brill, Herbert⋅Avitzur, Yaron⋅Avitzur, Yaron⋅Mercimek-Andrews, Saadet and Mercimek-Andrews, SaadetAmerican journal of medical genetics. Part A, January 14, 2021.
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2020
Caspase-8-Dependent Inflammatory Responses Are Controlled by Its Adaptor, FADD, and NecroptosisTummers, Bart⋅Mari, Luigi⋅Guy, Clifford S⋅Heckmann, Bradlee L⋅Rodriguez, Diego A⋅Rühl, Sebastian⋅Moretti, Julien⋅Fitzgerald, Patrick⋅Janke, Laura J⋅Pelletier, Stephane and Green, Douglas RImmunity, vol. 52, (no. 6), pp. 994-1006.e8, Jun 16, 2020.
| Journal Article
